In vivo analysis of proprioceptive coding and its antidromic modulation in the freely behaving crayfish

Journal of Neurophysiology

Volumn 94, Issue 2, 2005, Pages 1013-1027

  Le Ray, Didier ^a,b   Combes, Denis ^a,b   Déjean, Cyril ^a   Cattaert, Daniel ^a,b  

^a UNIVERSITÉ DE BORDEAUX   (France)

^b CNRS   (France)

Author keywords

[No Author keywords available]

Indexed keywords

ANIMAL EXPERIMENT; ANTIDROMIC STIMULATION; ARTICLE; BEHAVIOR; BIOMECHANICS; CELL TYPE; COXO BASIPODITE JOINT; CRAYFISH; ELECTROMYOGRAPHY; IN VIVO STUDY; INFORMATION PROCESSING; JOINT; JOINT FUNCTION; MOTOR ACTIVITY; NERVE CELL PLASTICITY; NERVE POTENTIAL; NONHUMAN; PRIORITY JOURNAL; PROPRIOCEPTION; SENSORY NERVE; SENSORY NERVE CELL; SPIKE; WALKING;

EID: 23044455819     PISSN: 00223077     EISSN: None     Source Type: Journal    
DOI: 10.1152/jn.01255.2004     Document Type: Article

References (51)

1. Beloozerova I and Rossignol S. Antidromic discharges in dorsal roots of decerebrate cats. I. Studies at rest and during fictive locomotion. Brain Res 846: 87-105, 1999.
2. Bévengut M, Clarac F, and Cattaert D. Antidromic modulation of a proprioceptor sensory discharge in crayfish. J Neurophysiol 78: 1180-1183, 1997.
3. Böhm H. Activity of the stomatogastric system in free-moving crayfish (Orconectes limosus R.). Zoology 99: 247-257, 1996.
4. Cattaert D and Bévengut M. Effects of antidromic discharges in crayfish primary afferents. J Neurophysiol 88: 1753-1765, 2002.
5. Cattaert D and Clarac F. Influence of walking on swimmeret beating in the lobster Homarus gammarus. J Neurobiol 14: 421-439, 1983.
6. Cattaert D, El Manira A, and Bévengut M. Presynaptic inhibition and antidromic discharges in crayfish primary afferents. J Physiol (Paris) 93: 349-358, 1999.
7. Cattaert D, El Manira A, and Clarac F. Direct evidence for presynaptic inhibitory mechanisms in crayfish sensory afferents. J Neurophysiol 67: 610-624, 1992.
8. Cattaert D, Le Bon M, and Le Ray D. Efferent controls in crustacean mechanoreceptors. Microsc Res Techn 58: 312-324, 2002.
9. Cattaert D and Le Ray D. Direct glutamate-mediated presynaptic inhibition of sensory afferents by the postsynaptic motor neurons. Eur J Neurosci 10: 3737-3746, 1998.
10. Cattaert D and Le Ray D. Adaptive motor control in crayfish. Prog Neurobiol 63: 199-240, 2001.
11. Cattaert D, Libersat F, and El Manira A. Presynaptic inhibition and antidromic spikes in primary afferents of the crayfish: a computational and experimental analysis. J Neurosci 21: 1007-1021, 2001.
12. Cokl A and Virant-Doberlet M. Communication with substrate-borne signals in small plant-dwelling insects. Annu Rev Entomol 48: 29-50, 2003.
13. Côté MP and Gossard JP. Task-dependent presynaptic inhibition. J Neurosci 23: 1886-1893, 2003.
14. Domemci P, Jamon M, and Clarac F. Curve walking in freely moving crayfish (Procambarus clarkii). J Exp Biol 201: 1315-1329, 1998.
15. Dubuc R, Cabelguen JM, and Rossignol S. Rhythmic antidromic discharges of single primary afferents recorded in cut dorsal root filament during locomotion in the cat. Brain Res 359: 375-378, 1985.
16. Dubuc R, Cabelguen JM, and Rossignol S. Rhythmic fluctuation of dorsal root potentials and antidromic discharges of primary afferents during fictive locomotion in the cat. J Neurophysiol 60: 2014-2036, 1988.
17. Duenas SH, Loeb GE, and Marks WB. Monosynaptic and dorsal root reflexes during locomotion in normal and thalamic cats. J Neurophysiol 63: 1467-1476, 1990.
18. Duysens J, Clarac F, and Cruse H. Load-regulating mechanisms in gait and posture: comparative aspects. Physiol Rev 80: 83-133, 2000.
19. Ellaway PH. Cumulative sum technique and its application to the analysis of peristimulus time histograms. Electroencephalogr Clin Neurophysiol 45: 302-304, 1978.
20. El Manira A and Clarac F. Presynaptic inhibition is mediated by histamine and GABA in the crustacean escape reaction. J Neurophysiol 71: 1088-1095, 1994.
21. Fellippa-Marques S, Vinay L, and Clarac F. Spontaneous and locomotor-related GABAergic input onto primary afferents in the neonatal rat. Eur J Neurosci 12: 155-164, 2000.
22. Garnett R and Stephens JA. The reflex response of single motor units in human first dorsal interosseus muscle following cutaneous afferent stimulation. J Physiol 303: 351-364, 1980.
23. Gopfert MC, Stocker H, and Robert D. Atonal is required for exoskeletal joint formation in the Drosophila auditory system. Dev Dyn 225: 106-109, 2002.
24. Gossard JP, Bouyer L, and Rossignol S. The effects of antidromic discharges on orthodromic firing of primary afferents in the cat. Brain Res 825: 132-145, 1999.
25. Gossard JP, Cabelguen JM, and Rossignol S. Intra-axonal recordings of cutaneous primary afferents during fictive locomotion in the cat. J Neurophysiol 62: 1177-1187, 1989.
26. Gossard JP, Cabelguen JM, and Rossignol S. An intracellular study of muscle primary afferents during fictive locomotion in the cat. J Neurophysiol 65: 914-926, 1991.
27. Hasan Z and Stuart DG. Animal solutions to problems of movement control: the role of proprioceptors. Ann Rev Neurosci 11: 199-223, 1988.
28. Jamon M and Clarac F. Locomotor patterns in freely moving crayfish (Procambarus clarkii). J Exp Biol 198: 683-700, 1995.
29. Jamon M and Clarac F. Variability of leg kinematics in free-walking crayfish, Procambarus clarkii, and related inter-joint coordination. J Exp Biol 200: 1201-1213, 1997.
30. Le Bon-Jego M and Cattaert D. Inhibitory component of the resistance reflex in the locomotor network of the crayfish. J Neurophysiol 88: 2575-2588, 2002.
31. Le Bon-Jego M, Cattaert D, and Pearlstein E. Serotonin enhances the resistance reflex of the locomotor network of the crayfish through multiple modulatory effects that act cooperatively. J Neurosci 24: 398-411, 2004.
32. Le Ray D and Cattaert D. Active motor neurons potentiate their own sensory inputs through retrograde glutamate-induced LTP. J Neurosci 19: 1473-1483, 1999.
33. Le Ray D, Clarac F, and Cattaert D. Functional analysis of the sensory motor pathway of resistance reflex in crayfish. I. Multisensory coding and motor neuron monosynaptic responses. J Neurophysiol 78: 3133-3143, 1997a.
34. Le Ray D, Clarac F, and Cattaert D. Functional analysis of the sensory motor pathway of resistance reflex in crayfish. II. Integration of sensory inputs in motor neurons. J Neurophysiol 78: 3144-3153, 1997b.
35. Loeb GE. Hard lessons in motor control from the mammalian spinal cord. Trends Neurosci 10: 108-113, 1987.
36. Marchand AR, Barnes WJ, and Cattaert D. Primary afferent depolarization of sensory origin within contact-sensitive mechanoreceptive afferents of a crayfish leg. J Neurophysiol 77: 3340-3354, 1997.
37. Marchand AR and Leibrock CS. Functional aspects of central electrical coupling in mechanoreceptor afferents of crayfish. Brain Res 667: 98-106, 1994.
38. Marrelli JD and Hsiao HS. Miniature angle transducer for marine arthropods. Comp Biochem Physiol A 54: 121-123, 1976.
39. Mattei B, Schmied A, and Vedel JP. Recurrent inhibition of wrist extensor motoneurones: a single unit study in a deafferented patient. J Physiol 549: 975-984, 2003.
40. McCrea DA. Spinal circuitry of sensorimotor control of locomotion. J Physiol 533: 41-50, 2001.
41. Newland PL, Cattaert D, Neil DM, and Clarac F. Steering reactions as adaptive components of the tail-flip in the spiny lobster Jasus lalandii. J Exp Biol 164: 261-282, 1992.
42. Roll JP, Bergenheim M, and Ribot-Ciscar E. Proprioceptive population coding of two-dimensional limb movements in humans: II. Muscle-spindle feedback during "drawing-like" movements. Exp Brain Res 134: 311-321, 2000.
43. Rudomin P. Selectivity of the central control of sensory information in the mammalian spinal cord. Adv Exp Med Biol 508: 157-170, 2002.
44. Rudomin P, Quevedo J, and Eguibar JR. Presynaptic modulation of spinal reflexes. Curr Opin Neurobiol 3: 997-1004, 1993.
45. Sillar KT and Skorupski P. Central input to primary afferent neurons in crayfish, Pacifastacus leniusculus, is correlated with rhythmic motor output of the thoracic ganglia. J Neurophysiol 55: 678-688, 1986.
46. Slesinger P and Bell CC. Primary afferent fibers conduct impulses in both directions under physiological stimulus conditions. J Comp Physiol 157: 15-22, 1985.
47. Stein W and Sauer AE. Physiology of vibration-sensitive afferents in the femoral chordotonal organ of the stick insect. J Comp Physiol 184: 253-263, 1999.
48. Vinay L, Brocard F, Fellippa-Marques S, and Clarac F. Antidromic discharges of dorsal root afferents in the neonatal rat. J Physiol (Paris) 93: 359-367, 1999.
49. Vinay L and Clarac F. Antidromic discharges of dorsal root afferents and inhibition of the lumbar monosynaptic reflex in the neonatal rat. Neuroscience 90: 165-176, 1999.
50. Westberg KG, Kolta A, Clavelou P, Sandström G, and Lund J. Evidence for functional compartmentalization of trigeminal muscle spindle afferents during fictive mastication in the rabbit. Eur J Neurosci 12: 1145-1154, 2000.
51. Wildman M and Cannone A. Sensory feedback and central afferent interaction in the muscle receptor organ of the crab, Carcinus maenas. J Neurophysiol 76: 788-798, 1996.